Coagulation–bubbling–ultrafiltration: Effect of floc properties on the performance of the hybrid process

A novel hybrid process of coagulation–bubbling–ultrafiltration was proposed to study membrane fouling phenomena by surface water. Relationship of bubbles, flocs and the hollow fibers was explored. When applying less than 20mL/min gas flow rate, membrane fouling was accelerated with air bubbles intro...

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Bibliographic Details
Published in:Desalination 2014-01, Vol.333 (1), p.126-133
Main Authors: Liu, Jianwei, Liu, Baicang, Liu, Tao, Bai, Yang, Yu, Shuili
Format: Article
Language:English
Subjects:
Air bubbles
Applied sciences
Blockage
Bubbles
Bubbling
Chemical engineering
Coagulation
Continental surface waters
Exact sciences and technology
Floc properties
Fouling
Gas flow
Hybrid process
Membrane separation (reverse osmosis, dialysis...)
Membranes
Natural water pollution
Pollution
Shear rate
Ultrafiltration
Water treatment and pollution
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Summary:A novel hybrid process of coagulation–bubbling–ultrafiltration was proposed to study membrane fouling phenomena by surface water. Relationship of bubbles, flocs and the hollow fibers was explored. When applying less than 20mL/min gas flow rate, membrane fouling was accelerated with air bubbles introduced. When gas flow rate increased further to 40mL/min and 60mL/min, TMP showed a two-stage development trend, which was a fast development in the first few hours followed with a relatively slow development after about 4h. Unified membrane fouling index (UMFI) increased from 0.00216 (without bubbles) to 0.00274m2/L (40mL/min gas flow rate) and 0.00219m2/L (60mL/min gas flow rate). As gas flow rate increased, bubble size became bigger, and its distribution range became wider, resulting in higher shear rate in the ultrafiltration column, which led to severe floc breakage. Flocs of small size and compact structure accelerated membrane fouling, resulting in highest UMFI value under 40mL/min gas flow rate. However, under 60mL/min gas flow rate, with largest bubbles and highest shear rate examined in this study, concentration polarization was effectively limited. As a result, TMP development slowed down when pore blockage reached equilibrium. •A novel hybrid process of coagulation–bubbling–ultrafiltration was proposed.•Relationship of air bubble size and gas flow rate was studied.•Bubbles and floc properties were measured to explain membrane performance.•Concentration polarization resistance was reduced with air bubbles injected.•Floc separation by air bubbles holds great promise in reducing membrane fouling potential.
ISSN:0011-9164
1873-4464
DOI:10.1016/j.desal.2013.11.029